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  <front>
    <journal-meta>
      <journal-title-group>
        <journal-title>Журнал Современные проблемы науки и образования</journal-title>
      </journal-title-group>
      <issn>2070-7428</issn>
      <publisher>
        <publisher-name>Общество с ограниченной ответственностью &amp;quot;Издательский Дом &amp;quot;Академия Естествознания&amp;quot;</publisher-name>
      </publisher>
    </journal-meta>
    <article-meta>
      <article-id pub-id-type="publisher-id">ART-7213</article-id>
      <title-group>
        <article-title>ИССЛЕДОВАНИЕ ФИЗИКО-МЕХАНИЧЕСКИХ СВОЙСТВ ЗАЩИТНЫХ КОМПОЗИЦИОННЫХ ПОКРЫТИЙ НА ОСНОВЕ ПОЛИФЕНИЛЕНСУЛЬФИДА</article-title>
      </title-group>
      <contrib-group>
        <contrib contrib-type="author">
          <name-alternatives>
            <name xml:lang="ru">
              <surname>Ергин</surname>
              <given-names>К.С.</given-names>
            </name>
          </name-alternatives>
          <name-alternatives>
            <name xml:lang="en">
              <surname>Ergin</surname>
              <given-names>K.S.</given-names>
            </name>
          </name-alternatives>
          <email>kostya_yergin@mail.ru</email>
          <xref ref-type="aff" rid="aff396fe74b"/>
        </contrib>
        <contrib contrib-type="author">
          <name-alternatives>
            <name xml:lang="ru">
              <surname>Чердынцев</surname>
              <given-names>В.В.</given-names>
            </name>
          </name-alternatives>
          <name-alternatives>
            <name xml:lang="en">
              <surname>Cherdyntsev</surname>
              <given-names>V.V.</given-names>
            </name>
          </name-alternatives>
          <email>vvch@misis.ru</email>
          <xref ref-type="aff" rid="aff396fe74b"/>
        </contrib>
        <contrib contrib-type="author">
          <name-alternatives>
            <name xml:lang="ru">
              <surname>Калошкин</surname>
              <given-names>С.Д.</given-names>
            </name>
          </name-alternatives>
          <name-alternatives>
            <name xml:lang="en">
              <surname>Kaloshkin</surname>
              <given-names>S.D.</given-names>
            </name>
          </name-alternatives>
          <email>kaloshkin@misis.ru</email>
          <xref ref-type="aff" rid="aff396fe74b"/>
        </contrib>
      </contrib-group>
      <aff id="aff396fe74b">
        <institution xml:lang="ru">Национальный исследовательский технологический университет "МИСиС"</institution>
        <institution xml:lang="en">National University of Science and Technology “MISIS”</institution>
      </aff>
      <pub-date date-type="pub" iso-8601-date="2012-05-19">
        <day>19</day>
        <month>05</month>
        <year>2012</year>
      </pub-date>
      <issue>5</issue>
      <fpage>128</fpage>
      <lpage>128</lpage>
      <permissions>
        <license xlink:href="https://creativecommons.org/licenses/by/4.0/">
          <license-p>This is an open-access article distributed under the terms of the CC BY 4.0 license.</license-p>
        </license>
      </permissions>
      <self-uri content-type="url" hreflang="ru">https://science-education.ru/ru/article/view?id=7213</self-uri>
      <abstract xml:lang="ru" lang-variant="original" lang-source="author">
        <p>Методом механоактивации получены порошковые композиционные материалы на основе полифениленсульфида с последующим нанесением на подложку в качестве защитного покрытия. В качестве подложки использовались Сталь 45, Сталь 08Х18Н10, Чугун СЧ21, Титан Вт-1-0, магниевый сплав АМг2 и латунь ЛАМш. Для достижения максимальных физико-механических свойств материал основного защитного слоя формировался по схеме многокомпонентного и многоуровнего композита, оптимальным образом использующего полезные свойства матричного и упрочняющего материалов. В качестве упрочняющей фазы твердофазным методом вводились в полимер разномасштабные металлические, керамические и алюмосиликатные порошки. Все типы покрытий показали хорошие физико-механические свойства. Введение наполнителей в полимерную матрицу на базе полифениленсульфида положительно сказалось на снижении коэффициента трения и уровня износа</p>
      </abstract>
      <abstract xml:lang="en" lang-variant="translation" lang-source="translator">
        <p>Powder of composite materials based on polyphenylene sulfide was obtained by the method of mechanical activation followed by application on substrate as a protective coating. The substrate was made of steel 45 08H18N10 Steel, Cast Iron SCH21, Titanium W-1-0, magnesium alloy and brass AMg2 LAMsh. To maximize the physico-mechanical properties the material of the main protective layer was formed as a multi-level and multi-component composite, optimally utilizing the useful properties of the matrix and reinforcement materials. Polymer matrix was filled by solid-state method with the hardening phase introduced by various scale polymer, metal, ceramic and silica-alumina powders. All types of coatings show good physico-mechanical properties. Introduction of fillers in polymer matrix based on reduce friction coefficient and wear.</p>
      </abstract>
      <kwd-group xml:lang="ru">
        <kwd>полифениленсульфид</kwd>
        <kwd>покрытия</kwd>
        <kwd>твердость</kwd>
        <kwd>ударная прочность</kwd>
        <kwd>износостойкость</kwd>
      </kwd-group>
      <kwd-group xml:lang="en">
        <kwd>PPS</kwd>
        <kwd>coatings</kwd>
        <kwd>hardness</kwd>
        <kwd>impact strength</kwd>
        <kwd>wear</kwd>
      </kwd-group>
    </article-meta>
  </front>
  <back>
    <ref-list>
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  </back>
</article>
